The invention relates to a rotary drill stem component for exploration of a hydrocarbon well with drilling mud in movement around the component from a bottom of the well towards the surface. The drill can include a central tubular element having an axis of revolution and extended on either side respectively by a first and a second tool joint each respectively and successively including a first cylindrical portion connected to the tubular element, a second tapered portion, a third cylindrical portion with a radius greater than that of the tubular element. The drill can include a threaded end which can connect the component to another component, the component including a first shell provided with one or more functional zones, the first shell being mounted on one of the tool joints in a cohesive and removable manner.
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1. A rotary drill stem component for exploration of a hydrocarbon well with drilling mud in movement around the component from a bottom of the well towards a surface, the component comprising:
a central tubular element having an axis of revolution and extended on either side respectively by a first and a second tool joint each respectively and successively comprising a first cylindrical portion connected to the tubular element, a second tapered portion, a third cylindrical portion with a radius which is greater than that of the tubular element, and a threaded end which can connect the component to another component, the component comprising a shell with one or more functional zones,
wherein the shell is mounted on one of the tool joints in a cohesive and removable manner,
wherein the shell is screwed against the tapered second portion of one of the tool joints using screws accommodated in housings formed in the shell and in the tapered portion and coaxial therewith, and
wherein the shell is fixed against the second tapered portion of one of the tool joints using at least one pin passing through the shell, the pin being fixed at one of its ends in a recess formed in the tool joint and by a nut screwed onto the other end of the pin.
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11. A rotary drill stem component according to the
12. A rotary drill stem component according to
13. A string of components of a rotary drill stem, wherein a component in accordance with
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1. Field of Disclosure
The invention relates to drill stem components used for the rotary drilling of oil or gas fields. In particular, the invention is applicable to components used in a drill stem such as drill pipes or heavy weight drill pipes, for example.
2. Description of Related Art
Rotary drill pipes connected together to form drill strings and associated with other components of the drill stem (drill collars, stabilizers, etc) can be used to produce deviated bores, i.e. bores wherein the inclination to the vertical or the horizontal direction can be varied during drilling. Deviated bores can currently reach depths of the order of 2 to 8 km and horizontal distances of the order of 2 to 15 km.
However, in the case of deviated holes, a number of problems arise which are directly linked to the variation in the inclination of the bore.
Firstly, on sections of drill strings that are almost horizontal, frictional torques may reach very high values during drilling under the effect of the weight of the components employed on those sections. This results in premature wear of the components employed on those sections.
Next, because the hole is no longer rectilinear, it is much more difficult for mud loaded with debris derived from excavating the rock to ascend when it is not straight. This results in poor cleaning of the hole and an increase both in the coefficients of friction of the pipes of the drill string inside the drilled hole and the contact surfaces between the pipes and the walls of the hole.
Finally, because the trajectory followed by the drill string is no longer rectilinear, it appears that the distribution of vibrations along such strings is no longer homogeneous. For this reason, bending stress concentrations that are over the admissible limits risk damaging the drill strings in certain regions.
In order to overcome these disadvantages, the prior art has proposed a variety of arrangements.
Thus, document FR 2 851 608 describes a drill pipe provided with a bearing zone having a hard coating so that at that region, the contact surface with the walls of the hole is wear-resistant. Furthermore, activation zones which are helical in shape can accelerate the ascent of drilling fluid and debris derived from drilling.
Similarly, document FR 2 835 014 proposes drill pipe profiles with depressions and projections which are arranged to facilitate the ascent of drilling debris.
Clearly, those solutions have produced very satisfactory results. However, the current solutions require that the drilling components be machined in order to obtain the activation zones, and the bearing zones of said components have to be treated in order to obtain a wear-resistant coating. More generally, adding such functions to the drilling components has a huge impact on the manufacture of such components.
Document WO-2005/93204 proposes a device that can be fixed on a drilling component in a removable manner and has functional zones which can facilitate the movement of drilling mud and the ascent of debris as well as progress of the component during drilling. The device is constituted by two half-shells connected together via a pivotal connection; the device docks with the drilling component by means of a clamping system which positions the half-shells flush against each other.
However, this solution suffers from the disadvantage of rendering the drilling component fragile. The fact that the device surrounds the component generates a zone with a high concentration of stresses. The effect of this is that the drilling component can break in service, or it can become detached from the device carrying the functional zones.
The invention proposes a drilling component comprising functional zones that are even more resistant in operation.
More precisely, a rotary drill stem component for exploration of a hydrocarbon well with drilling mud in movement around said component from the bottom of the well towards the surface comprises a central tubular element having an axis of revolution and extended on either side respectively by a first and a second tool joints each respectively and successively comprising a first, cylindrical, portion connected to the tubular element, a second, tapered, portion, a third, cylindrical, portion with a radius R which is greater than that of the tubular element, and a threaded end which can connect the component to another component. The component comprises a shell with one or more functional zones provided on its circumferential surface. The shell is mounted on one of the tool joints in a cohesive and removable manner.
Optional complementary or substitutional characteristics of the invention are defined below.
The shell may be screwed against the tapered portion of one of the tool joints using screws accommodated in housings which may be threaded, for example, formed in the shell and in the tapered portion and coaxial therewith.
The shell may be fixed against the second tapered portion of one of the tool joints using at least one pin passing through said shell, said pin being fixed at one of its ends in a recess formed in the tool joint and by means of a nut screwed onto the other end of the pin.
The internal circumferential surface of the shell constituted by two half-shells, and also the external circumferential surface of the third cylindrical portion of one of the tool joints may be complementary such that the first shell can be fitted onto the third cylindrical portion.
The component may comprise a first and a second shell, one of the two faces of the first shell being capable of being fitted into one of the two faces of the second shell, such that the shells are secured together by means of a bayonet type fitting.
The functional zones may comprise a first fluid activation zone downstream of which a first bearing zone is provided, downstream of which a second fluid activation zone is provided, downstream of which a second bearing zone is provided, and downstream of which a third fluid activation zone is provided, the terms “upstream” and “downstream” being defined with respect to the direction of movement of mud along said component.
Said activation zones may comprise a plurality of grooves hollowed into the surface of the shell(s) and extending in a helical manner about the axis of the central tubular component.
The surface on which the first activation zone is provided may be inclined in the upstream to downstream direction such that it draws further away from the axis of the central tubular element, in order to guide mud along the component.
The surface on which the second activation zone is provided may be concave in order to guide mud along the component.
The surface on which the third activation zone is provided may be inclined in the upstream to downstream direction such that it draws nearer to the axis of the central tubular element in order to guide mud along the component.
The surface on which the first and second bearing zones are provided may be convex in order to limit friction between the shell and the wall of the well.
The activation zones and the bearing zones may be connected together in a tangential manner.
The shell(s) may be mounted in a cohesive and removable manner on a tool joint provided with a threaded male end.
The invention also concerns a string of components of a rotary drill stem wherein a component in accordance with one embodiment of the invention is involved in the constitution of the drill pipe string with a periodicity equal to three.
The present invention will be better understood from the following detailed description of several embodiments given by way of entirely non-limiting examples and illustrated in the accompanying drawings, in which:
In order to resist mechanical stresses, the tubular components may have a section that increases in thickness as the drill bit is approached. Thus, on approaching the surface of the well, the drill pipes may have a central tube diameter which is smaller in order to economize on material, while the welded tool joints must retain a certain thickness in order to keep the connection portions reliable.
During rotary drilling, a drilling fluid is guided under pressure into the drill stem to the bottom of the well. Partly due to the pressure, it rises to the surface, entraining therewith debris from rocks excavated by the drill bit.
The tubular element 13 has an axis of revolution 10. The drilling component 1 also comprises a shell 2 which can be securely attached to one of the tool joints. The term “capable of being securely attached” means that the shell 2, once fixed, can neither translate nor turn with respect to the tool joint. Functional zones are applied to a shell 2, which shell is itself fixed on a component of the drill stem, either before said component is connected to others, or afterwards. The term “functional zones” means surfaces applied to the drilling components which may be used to accelerate the movement of mud around said components. These surfaces generally have particular shapes facilitating fluid flow. The term “functional zones” also means the surfaces attached to the drilling components, which are designed to accommodate shocks and friction arising during drilling. The term “functional zones” also means portions applied to the shell which house electronic components. These electronic components may be intended to measure, process and/or transmit signals.
Applying functional zones to a drill stem of the invention is simpler and more flexible. It is not necessary to machine and produce surface coatings directly on the tubular elements constituting the drill stem in order to obtain these activation zones. In other words, this means that additional equipment can be avoided as well as complex manufacturing steps. Further, the shells can be manufactured separately and the shell can be connected to the tubular elements away from the shop producing the tubular elements, or even at the drilling site (rig). Further, this means that only the shell needs to be changed, or only the tubular element if only one of the two is damaged. The fact that the shell is fixed on the tool joint and not on the tubular element 13 avoids the generation of stress concentrations at the tubular element which is much thinner than the tool joints. In other words, fixing the shell on the tool joints, which are much thicker than the tubular elements, is highly advantageous as it does not render the drilling components fragile.
Fixing the shell on a single tool joint 11, 12 of the two tool joints lets a great freedom in mounting. Fixing the shell on a single tool joint 11, 12 of the two tool joints exempts a strict order of assembly between the assembly of the shell 2 of a tool joint 11, 12 and screwing components 1 of a drill with each others. It can be mounted, in a first step, a shell 2 on a single of the two tool joints 11, 12, in a second step, screwing the two tool joints 11, 12 of two components 1 of a drill. It can be mounted, in a first step, a shell 2 on each of the two tool joints 11, 12, in a second step, screwing two tool joints 11, 12 of two components 1 of a drill. It can be screwed, in a first step, two tool joints 11, 12 of two components 1 of a drill, in a second step, fixing a shell 2 on a single of the two tool joints 11, 12. It can be screwed, in a first step, two tool joints 11, 12 of two components 1 of a drill, in a second step, fixing a shell 2 on each of the two tool joints 11, 12.
The shell 2 can be set in the tool joint in a variety of manners. According to one manner, the preliminary screwing of components 1 of a drill is independent of the fixing of (the) shell(s) 2 on the tool joint(s) 11, 12. According to one manner, the shell 2 can extend from the tool joint 11, 12 onto a portion of the tubular element 13. According to one manner, it can be provided with support elements between the outer circumferential surface of the tubular element 13 and the inner circumferential surface of the shell 2. Said support elements increase stability in translation and/or in rotation between the shell 2 and the stem of drill components. The support elements could comprise pins protruding in hollows.
In one embodiment shown in
In one embodiment shown in
In one embodiment shown in
In accordance with one embodiment shown in
Advantageously, one, 221, of the two faces of the first shell 2′ can be fitted against one, 211, of the two faces of the second shell 2″, such that the shells are secured together by means of a bayonet type mount.
The advantage of using two or even more shells is particularly interesting when each of the shells carries a single functional zone. This allows for great flexibility insofar as each drilling component can be provided with particular functions which depend on the manner in which it is used. As an example, it would be possible to specify that bearing zones are to be used for the drilling components employed in the horizontal portion C of the well.
In the embodiment shown in
In this manner, the shell can be fitted onto the tool joint. Clearly, the two half-shells may be fixed together with screws. As an example as shown in
In accordance with this embodiment detailed in
In order to facilitate the ascent of mud formed by the mixture of drilling fluid and debris, zones 22, 23 and 24 can be used to activate the flow of mud along the components, comprising grooves 220, 230, 240 formed on one portion of the external surface of the shells and extending in a helical manner about the axis 10 of the central tubular element.
In order to guide the mud along the component, the diameter of the shell increases in the upstream to downstream direction over the portion of the shell on which the first activation zone 22 is formed, this zone being the furthest upstream.
Similarly, the diameter of the shell decreases in the upstream to downstream direction over the portion of shell on which the third activation zone 23 is provided, this zone being the furthest downstream.
The fluid activation zones could be designed in accordance with the disclosures provided in French patent applications FR 2 789 438 and FR 2 835 014, herein incorporated by reference.
In order to reinforce the drilling components against shocks, the zones intended to bear on the wall of the well are completely or partially coated with materials with a high hardness.
In order to limit the friction between the shell and the well wall, the surface of the shell on which the first and second bearing zones 21, 25 are formed is convex.
In order to resist friction between the shell and the well wall, the first and second bearing zones 21, 25 have a diameter which is greater than the maximum diameter of the tubular element 13 and a hardness which is greater than the hardness of the tubular element 13.
The bearing zones could be designed in accordance with the disclosures provided in French application FR 2 851 608, hereby incorporated by reference.
Another concave intermediate activation zone 24 is provided between the two bearing zones 21, 25 in order to guide the mud along the component.
The activation zones and the bearing zones are connected together in a tangential manner.
The arrangement of the various functional zones may be selected in accordance with the disclosure in French application FR 2 927 937, hereby incorporated by reference.
For a drill stem such as that shown in
In contrast, in zones A and B, as surface 6 is approached, the spacing between the components provided with shells depends on the inclination of the well and the drilling parameters. Further, priority will have to be given to the fluid activation zones in order to contribute to lifting the mud to the surface.
Preferably, the shell is fixed on the tool joint carrying a male threaded zone. During assembly at the well, the drilling components arrive vertically in batches of n components which have already been assembled; currently, n=3. The end of the batch ready to be made up into the drill string advancing into the well generally carries a male threading, while the other end has a female threading. For this reason, it is easy to precede the operation for making up the batch onto the drill pipe string by an operation for mounting a shell or a set of shells. Further, the other end of the batch, in general carrying a female threading, is used for manipulation using elevators. In this case, the drill pipe string comprises components provided with shells with a periodicity equal to n, for example three. It is also possible to envisage having a different periodicity, such as 1.
The invention is not limited to the provision of fluid activation zones or bearing zones. The shell, and also the set of shells fixed on the tool joint, may be intended to house electronic components, for example intended for the measurement, processing and/or transmission of signals involved in the drilling operations.
Roussie, Gabriel, Rohart, Christophe
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Nov 15 2010 | Vam Drilling France | (assignment on the face of the patent) | / | |||
May 10 2012 | ROHART, CHRISTOPHE | Vam Drilling France | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 028271 | /0105 | |
May 11 2012 | ROUSSIE, GABRIEL | Vam Drilling France | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 028271 | /0105 | |
Oct 01 2013 | Vam Drilling France | VALLOUREC DRILLING PRODUCTS FRANCE | CHANGE OF NAME SEE DOCUMENT FOR DETAILS | 037207 | /0627 |
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